Provided herein are modified T lymphocytes comprising chimeric receptors and methods of use thereof.

Compositions, systems, and methods for reducing viability of cancer cells and treating cancer, as well as preventing an increase of volume of a tumor present in a body of a living subject, are disclosed. The systems and methods involve application of an alternating field concurrently with administration of at least one composition comprising at least one chimeric antigen receptor (CAR)-immune cell.

The disclosure provides novel antigen-binding proteins that bind STEAP1 and methods of use.

This invention provides ex vivo methods for making modified PBMC compositions having overall anti-fugetactic properties for the effective and efficient treatment of tumors or cancers in a patient, and compositions and use thereof, following treatment with an antigen presenting cell-based vaccine against a cancer antigen.

Compositions and methods are disclosed herein for producing one or more immunoglobulins in an isolated cytotoxic B lymphocyte cell line. An isolated cell line includes an isolated B lymphocyte cell line capable of expressing at least one exogenously incorporated membrane immunoglobulin capable of binding to a first antigen and at least one endogenous secreted immunoglobulin capable of binding to a second antigen, and further capable of expressing at least one exogenously incorporated recombinant B cell receptor that signals for expression of cytotoxic effector molecules.

The technology relates in part to methods for controlling the activity or elimination of therapeutic cells using molecular switches that employ distinct heterodimerizer ligands, in conjunction with other multimeric ligands. The technology may be used, for example to activate or eliminate cells used to promote engraftment, to treat diseases or condition, or to control or modulate the activity of therapeutic cells that express chimeric antigen receptors or recombinant T cell receptors.

Production and use of novel therapeutic cells, called T-Vehicles, in the allogeneic Adoptive Cell Therapy setting allows a wide range of therapeutic benefits to accrue with minimal or no risk of GVHD. T-Vehicles are created from donor T cells that are altered to contain therapeutic attributes that do not include their native antigen receptors and can deliver therapeutic benefits irrelevant of their native antigen specificity. T-Vehicles can possess highly restricted native antigen specificity that renders them unable to recognize antigens present on normal cells and incapable of initiating GVHD, making them ideal transport vehicles to deliver various therapeutic attributes in vivo. In essence, production and use of T-Vehicles is a paradigm shift that opens the door to therapeutic application of T cells in ways not previously contemplated, independent of whether or not there is an HLA match between the donor and the recipient.

Provided in the present invention are an improved hinge area and the use of same in constructing CAR skeleton. The amino acid sequence of the improved hinge area is as shown in SEQ ID NO.1 or SEQ ID NO.2 or SEQ ID NO.3, and the hinge area can prolong the survival of CAR-T cells in vivo and/or improve the capability of CAR-T cells to infiltrate tumors.